Google Git
Sign in
skia / skia / chrome/m37_2062 / . / gm / gmmain.cpp
blob: 364e771a36b75c52c612686626b70792878064b7 [file] [log] [blame]
/*
* Copyright 2011 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
/*
* Code for the "gm" (Golden Master) rendering comparison tool.
*
* If you make changes to this, re-run the self-tests at gm/tests/run.sh
* to make sure they still pass... you may need to change the expected
* results of the self-test.
*/
#include "gm.h"
#include "gm_error.h"
#include "gm_expectations.h"
#include "system_preferences.h"
#include "CrashHandler.h"
#include "Resources.h"
#include "SamplePipeControllers.h"
#include "SkBitmap.h"
#include "SkColorPriv.h"
#include "SkCommandLineFlags.h"
#include "SkData.h"
#include "SkDeferredCanvas.h"
#include "SkDevice.h"
#include "SkDocument.h"
#include "SkDrawFilter.h"
#include "SkForceLinking.h"
#include "SkGPipe.h"
#include "SkGraphics.h"
#include "SkImageDecoder.h"
#include "SkImageEncoder.h"
#include "SkJSONCPP.h"
#include "SkOSFile.h"
#include "SkPDFRasterizer.h"
#include "SkPicture.h"
#include "SkPictureRecorder.h"
#include "SkRefCnt.h"
#include "SkScalar.h"
#include "SkStream.h"
#include "SkString.h"
#include "SkSurface.h"
#include "SkTArray.h"
#include "SkTDict.h"
#ifdef SK_DEBUG
static const bool kDebugOnly = true;
#define GR_DUMP_FONT_CACHE 0
#else
static const bool kDebugOnly = false;
#endif
__SK_FORCE_IMAGE_DECODER_LINKING;
#if SK_SUPPORT_GPU
#include "GrContextFactory.h"
#include "SkGpuDevice.h"
typedef GrContextFactory::GLContextType GLContextType;
#define DEFAULT_CACHE_VALUE -1
static int gGpuCacheSizeBytes;
static int gGpuCacheSizeCount;
#else
class GrContextFactory;
class GrContext;
class GrSurface;
typedef int GLContextType;
#endif
#define DEBUGFAIL_SEE_STDERR SkDEBUGFAIL("see stderr for message")
DECLARE_bool(useDocumentInsteadOfDevice);
#ifdef SK_SUPPORT_PDF
#include "SkPDFDevice.h"
#include "SkPDFDocument.h"
#endif
// Until we resolve http://code.google.com/p/skia/issues/detail?id=455 ,
// stop writing out XPS-format image baselines in gm.
#undef SK_SUPPORT_XPS
#ifdef SK_SUPPORT_XPS
#include "SkXPSDevice.h"
#endif
#ifdef SK_BUILD_FOR_MAC
#include "SkCGUtils.h"
#endif
using namespace skiagm;
class Iter {
public:
Iter() {
this->reset();
}
void reset() {
fReg = GMRegistry::Head();
}
GM* next() {
if (fReg) {
GMRegistry::Factory fact = fReg->factory();
fReg = fReg->next();
return fact(0);
}
return NULL;
}
static int Count() {
const GMRegistry* reg = GMRegistry::Head();
int count = 0;
while (reg) {
count += 1;
reg = reg->next();
}
return count;
}
private:
const GMRegistry* fReg;
};
// TODO(epoger): Right now, various places in this code assume that all the
// image files read/written by GM use this file extension.
// Search for references to this constant to find these assumptions.
const static char kPNG_FileExtension[] = "png";
enum Backend {
kRaster_Backend,
kGPU_Backend,
kPDF_Backend,
kXPS_Backend,
};
enum BbhType {
kNone_BbhType,
kRTree_BbhType,
kTileGrid_BbhType,
kQuadTree_BbhType
};
enum ConfigFlags {
kNone_ConfigFlag = 0x0,
/* Write GM images if a write path is provided. */
kWrite_ConfigFlag = 0x1,
/* Read reference GM images if a read path is provided. */
kRead_ConfigFlag = 0x2,
kRW_ConfigFlag = (kWrite_ConfigFlag | kRead_ConfigFlag),
};
struct ConfigData {
SkColorType fColorType;
Backend fBackend;
GLContextType fGLContextType; // GPU backend only
int fSampleCnt; // GPU backend only
ConfigFlags fFlags;
const char* fName;
bool fRunByDefault;
};
struct PDFRasterizerData {
bool (*fRasterizerFunction)(SkStream*, SkBitmap*);
const char* fName;
bool fRunByDefault;
};
class BWTextDrawFilter : public SkDrawFilter {
public:
virtual bool filter(SkPaint*, Type) SK_OVERRIDE;
};
bool BWTextDrawFilter::filter(SkPaint* p, Type t) {
if (kText_Type == t) {
p->setAntiAlias(false);
}
return true;
}
struct PipeFlagComboData {
const char* name;
uint32_t flags;
};
static PipeFlagComboData gPipeWritingFlagCombos[] = {
{ "", 0 },
{ " cross-process", SkGPipeWriter::kCrossProcess_Flag },
{ " cross-process, shared address", SkGPipeWriter::kCrossProcess_Flag
| SkGPipeWriter::kSharedAddressSpace_Flag }
};
static SkData* encode_to_dct_data(size_t* pixelRefOffset, const SkBitmap& bitmap);
DECLARE_int32(pdfRasterDpi);
const static ErrorCombination kDefaultIgnorableErrorTypes = ErrorCombination()
.plus(kMissingExpectations_ErrorType)
.plus(kIntentionallySkipped_ErrorType);
class GMMain {
public:
GMMain() : fUseFileHierarchy(false), fWriteChecksumBasedFilenames(false),
fIgnorableErrorTypes(kDefaultIgnorableErrorTypes),
fMismatchPath(NULL), fMissingExpectationsPath(NULL), fTestsRun(0),
fRenderModesEncountered(1) {}
/**
* Assemble shortNamePlusConfig from (surprise!) shortName and configName.
*
* The method for doing so depends on whether we are using hierarchical naming.
* For example, shortName "selftest1" and configName "8888" could be assembled into
* either "selftest1_8888" or "8888/selftest1".
*/
SkString make_shortname_plus_config(const char *shortName, const char *configName) {
SkString name;
if (0 == strlen(configName)) {
name.append(shortName);
} else if (fUseFileHierarchy) {
name.appendf("%s%c%s", configName, SkPATH_SEPARATOR, shortName);
} else {
name.appendf("%s_%s", shortName, configName);
}
return name;
}
/**
* Assemble filename, suitable for writing out the results of a particular test.
*/
SkString make_filename(const char *path,
const char *shortName,
const char *configName,
const char *renderModeDescriptor,
const char *suffix) {
SkString filename = make_shortname_plus_config(shortName, configName);
filename.append(renderModeDescriptor);
filename.appendUnichar('.');
filename.append(suffix);
return SkOSPath::SkPathJoin(path, filename.c_str());
}
/**
* Assemble filename suitable for writing out an SkBitmap.
*/
SkString make_bitmap_filename(const char *path,
const char *shortName,
const char *configName,
const char *renderModeDescriptor,
const GmResultDigest &bitmapDigest) {
if (fWriteChecksumBasedFilenames) {
SkString filename;
filename.append(bitmapDigest.getHashType());
filename.appendUnichar('_');
filename.append(shortName);
filename.appendUnichar('_');
filename.append(bitmapDigest.getDigestValue());
filename.appendUnichar('.');
filename.append(kPNG_FileExtension);
return SkOSPath::SkPathJoin(path, filename.c_str());
} else {
return make_filename(path, shortName, configName, renderModeDescriptor,
kPNG_FileExtension);
}
}
/* since PNG insists on unpremultiplying our alpha, we take no
precision chances and force all pixels to be 100% opaque,
otherwise on compare we may not get a perfect match.
*/
static void force_all_opaque(const SkBitmap& bitmap) {
SkColorType colorType = bitmap.colorType();
switch (colorType) {
case kN32_SkColorType:
force_all_opaque_8888(bitmap);
break;
case kRGB_565_SkColorType:
// nothing to do here; 565 bitmaps are inherently opaque
break;
default:
SkDebugf("unsupported bitmap colorType %d\n", colorType);
DEBUGFAIL_SEE_STDERR;
}
}
static void force_all_opaque_8888(const SkBitmap& bitmap) {
SkAutoLockPixels lock(bitmap);
for (int y = 0; y < bitmap.height(); y++) {
for (int x = 0; x < bitmap.width(); x++) {
*bitmap.getAddr32(x, y) |= (SK_A32_MASK << SK_A32_SHIFT);
}
}
}
static ErrorCombination write_bitmap(const SkString& path, const SkBitmap& bitmap) {
// TODO(epoger): Now that we have removed force_all_opaque()
// from this method, we should be able to get rid of the
// transformation to 8888 format also.
SkBitmap copy;
bitmap.copyTo(&copy, kN32_SkColorType);
if (!SkImageEncoder::EncodeFile(path.c_str(), copy,
SkImageEncoder::kPNG_Type,
100)) {
SkDebugf("FAILED to write bitmap: %s\n", path.c_str());
return ErrorCombination(kWritingReferenceImage_ErrorType);
}
return kEmpty_ErrorCombination;
}
/**
* Add all render modes encountered thus far to the "modes" array.
*/
void GetRenderModesEncountered(SkTArray<SkString> &modes) {
SkTDict<int>::Iter iter(this->fRenderModesEncountered);
const char* mode;
while ((mode = iter.next(NULL)) != NULL) {
SkString modeAsString = SkString(mode);
// TODO(epoger): It seems a bit silly that all of these modes were
// recorded with a leading "-" which we have to remove here
// (except for mode "", which means plain old original mode).
// But that's how renderModeDescriptor has been passed into
// compare_test_results_to_reference_bitmap() historically,
// and changing that now may affect other parts of our code.
if (modeAsString.startsWith("-")) {
modeAsString.remove(0, 1);
}
modes.push_back(modeAsString);
}
}
/**
* Returns true if failures on this test should be ignored.
*/
bool ShouldIgnoreTest(const char *name) const {
for (int i = 0; i < fIgnorableTestNames.count(); i++) {
if (fIgnorableTestNames[i].equals(name)) {
return true;
}
}
return false;
}
/**
* Calls RecordTestResults to record that we skipped a test.
*
* Depending on the backend, this may mean that we skipped a single rendermode, or all
* rendermodes; see http://skbug.com/1994 and https://codereview.chromium.org/129203002/
*/
void RecordSkippedTest(const SkString& shortNamePlusConfig,
const char renderModeDescriptor [], Backend backend) {
if (kRaster_Backend == backend) {
// Skipping a test on kRaster_Backend means that we will skip ALL renderModes
// (as opposed to other backends, on which we only run the default renderMode).
//
// We cannot call RecordTestResults yet, because we won't know the full set of
// renderModes until we have run all tests.
fTestsSkippedOnAllRenderModes.push_back(shortNamePlusConfig);
} else {
this->RecordTestResults(kIntentionallySkipped_ErrorType, shortNamePlusConfig,
renderModeDescriptor);
}
}
/**
* Records the results of this test in fTestsRun and fFailedTests.
*
* We even record successes, and errors that we regard as
* "ignorable"; we can filter them out later.
*/
void RecordTestResults(const ErrorCombination& errorCombination,
const SkString& shortNamePlusConfig,
const char renderModeDescriptor []) {
// Things to do regardless of errorCombination.
fTestsRun++;
int renderModeCount = 0;
this->fRenderModesEncountered.find(renderModeDescriptor, &renderModeCount);
renderModeCount++;
this->fRenderModesEncountered.set(renderModeDescriptor, renderModeCount);
if (errorCombination.isEmpty()) {
return;
}
// Things to do only if there is some error condition.
SkString fullName = shortNamePlusConfig;
fullName.append(renderModeDescriptor);
for (int typeInt = 0; typeInt <= kLast_ErrorType; typeInt++) {
ErrorType type = static_cast<ErrorType>(typeInt);
if (errorCombination.includes(type)) {
fFailedTests[type].push_back(fullName);
}
}
}
/**
* Return the number of significant (non-ignorable) errors we have
* encountered so far.
*/
int NumSignificantErrors() {
int significantErrors = 0;
for (int typeInt = 0; typeInt <= kLast_ErrorType; typeInt++) {
ErrorType type = static_cast<ErrorType>(typeInt);
if (!fIgnorableErrorTypes.includes(type)) {
significantErrors += fFailedTests[type].count();
}
}
return significantErrors;
}
/**
* Display the summary of results with this ErrorType.
*
* @param type which ErrorType
* @param verbose whether to be all verbose about it
*/
void DisplayResultTypeSummary(ErrorType type, bool verbose) {
bool isIgnorableType = fIgnorableErrorTypes.includes(type);
SkString line;
if (isIgnorableType) {
line.append("[ ] ");
} else {
line.append("[*] ");
}
SkTArray<SkString> *failedTestsOfThisType = &fFailedTests[type];
int count = failedTestsOfThisType->count();
line.appendf("%d %s", count, getErrorTypeName(type));
if (!isIgnorableType || verbose) {
line.append(":");
for (int i = 0; i < count; ++i) {
line.append(" ");
line.append((*failedTestsOfThisType)[i]);
}
}
SkDebugf("%s\n", line.c_str());
}
/**
* List contents of fFailedTests to stdout.
*
* @param verbose whether to be all verbose about it
*/
void ListErrors(bool verbose) {
// First, print a single summary line.
SkString summary;
summary.appendf("Ran %d tests:", fTestsRun);
for (int typeInt = 0; typeInt <= kLast_ErrorType; typeInt++) {
ErrorType type = static_cast<ErrorType>(typeInt);
summary.appendf(" %s=%d", getErrorTypeName(type), fFailedTests[type].count());
}
SkDebugf("%s\n", summary.c_str());
// Now, for each failure type, list the tests that failed that way.
for (int typeInt = 0; typeInt <= kLast_ErrorType; typeInt++) {
this->DisplayResultTypeSummary(static_cast<ErrorType>(typeInt), verbose);
}
SkDebugf("(results marked with [*] will cause nonzero return value)\n");
}
static ErrorCombination write_document(const SkString& path, SkStreamAsset* asset) {
SkFILEWStream stream(path.c_str());
if (!stream.writeStream(asset, asset->getLength())) {
SkDebugf("FAILED to write document: %s\n", path.c_str());
return ErrorCombination(kWritingReferenceImage_ErrorType);
}
return kEmpty_ErrorCombination;
}
/**
* Prepare an SkBitmap to render a GM into.
*
* After you've rendered the GM into the SkBitmap, you must call
* complete_bitmap()!
*
* @todo thudson 22 April 2011 - could refactor this to take in
* a factory to generate the context, always call readPixels()
* (logically a noop for rasters, if wasted time), and thus collapse the
* GPU special case and also let this be used for SkPicture testing.
*/
static void setup_bitmap(const ConfigData& gRec, SkISize& size,
SkBitmap* bitmap) {
bitmap->allocPixels(SkImageInfo::Make(size.width(), size.height(),
gRec.fColorType, kPremul_SkAlphaType));
bitmap->eraseColor(SK_ColorTRANSPARENT);
}
/**
* Any finalization steps we need to perform on the SkBitmap after
* we have rendered the GM into it.
*
* It's too bad that we are throwing away alpha channel data
* we could otherwise be examining, but this had always been happening
* before... it was buried within the compare() method at
* https://code.google.com/p/skia/source/browse/trunk/gm/gmmain.cpp?r=7289#305 .
*
* Apparently we need this, at least for bitmaps that are either:
* (a) destined to be written out as PNG files, or
* (b) compared against bitmaps read in from PNG files
* for the reasons described just above the force_all_opaque() method.
*
* Neglecting to do this led to the difficult-to-diagnose
* http://code.google.com/p/skia/issues/detail?id=1079 ('gm generating
* spurious pixel_error messages as of r7258')
*
* TODO(epoger): Come up with a better solution that allows us to
* compare full pixel data, including alpha channel, while still being
* robust in the face of transformations to/from PNG files.
* Options include:
*
* 1. Continue to call force_all_opaque(), but ONLY for bitmaps that
* will be written to, or compared against, PNG files.
* PRO: Preserve/compare alpha channel info for the non-PNG cases
* (comparing different renderModes in-memory)
* CON: The bitmaps (and hash digests) for these non-PNG cases would be
* different than those for the PNG-compared cases, and in the
* case of a failed renderMode comparison, how would we write the
* image to disk for examination?
*
* 2. Always compute image hash digests from PNG format (either
* directly from the the bytes of a PNG file, or capturing the
* bytes we would have written to disk if we were writing the
* bitmap out as a PNG).
* PRO: I think this would allow us to never force opaque, and to
* the extent that alpha channel data can be preserved in a PNG
* file, we could observe it.
* CON: If we read a bitmap from disk, we need to take its hash digest
* from the source PNG (we can't compute it from the bitmap we
* read out of the PNG, because we will have already premultiplied
* the alpha).
* CON: Seems wasteful to convert a bitmap to PNG format just to take
* its hash digest. (Although we're wasting lots of effort already
* calling force_all_opaque().)
*
* 3. Make the alpha premultiply/unpremultiply routines 100% consistent,
* so we can transform images back and forth without fear of off-by-one
* errors.
* CON: Math is hard.
*
* 4. Perform a "close enough" comparison of bitmaps (+/- 1 bit in each
* channel), rather than demanding absolute equality.
* CON: Can't do this with hash digests.
*/
static void complete_bitmap(SkBitmap* bitmap) {
force_all_opaque(*bitmap);
}
static void installFilter(SkCanvas* canvas);
static void invokeGM(GM* gm, SkCanvas* canvas, bool isPDF, bool isDeferred) {
SkAutoCanvasRestore acr(canvas, true);
if (!isPDF) {
canvas->concat(gm->getInitialTransform());
}
installFilter(canvas);
gm->setCanvasIsDeferred(isDeferred);
gm->draw(canvas);
canvas->setDrawFilter(NULL);
}
static ErrorCombination generate_image(GM* gm, const ConfigData& gRec,
GrSurface* gpuTarget,
SkBitmap* bitmap,
bool deferred) {
SkISize size (gm->getISize());
setup_bitmap(gRec, size, bitmap);
const SkImageInfo info = bitmap->info();
SkAutoTUnref<SkSurface> surface;
SkAutoTUnref<SkCanvas> canvas;
if (gRec.fBackend == kRaster_Backend) {
surface.reset(SkSurface::NewRasterDirect(info,
bitmap->getPixels(),
bitmap->rowBytes()));
if (deferred) {
canvas.reset(SkDeferredCanvas::Create(surface));
} else {
canvas.reset(SkRef(surface->getCanvas()));
}
invokeGM(gm, canvas, false, deferred);
canvas->flush();
}
#if SK_SUPPORT_GPU
else { // GPU
surface.reset(SkSurface::NewRenderTargetDirect(gpuTarget->asRenderTarget()));
if (deferred) {
canvas.reset(SkDeferredCanvas::Create(surface));
} else {
canvas.reset(SkRef(surface->getCanvas()));
}
invokeGM(gm, canvas, false, deferred);
// the device is as large as the current rendertarget, so
// we explicitly only readback the amount we expect (in
// size) overwrite our previous allocation
bitmap->setInfo(SkImageInfo::MakeN32Premul(size.fWidth, size.fHeight));
canvas->readPixels(bitmap, 0, 0);
}
#endif
complete_bitmap(bitmap);
return kEmpty_ErrorCombination;
}
static void generate_image_from_picture(GM* gm, const ConfigData& gRec,
SkPicture* pict, SkBitmap* bitmap,
SkScalar scale = SK_Scalar1,
bool tile = false) {
SkISize size = gm->getISize();
setup_bitmap(gRec, size, bitmap);
if (tile) {
// Generate the result image by rendering to tiles and accumulating
// the results in 'bitmap'
// This 16x16 tiling matches the settings applied to 'pict' in
// 'generate_new_picture'
SkISize tileSize = SkISize::Make(16, 16);
SkBitmap tileBM;
setup_bitmap(gRec, tileSize, &tileBM);
SkCanvas tileCanvas(tileBM);
installFilter(&tileCanvas);
SkCanvas bmpCanvas(*bitmap);
SkPaint bmpPaint;
bmpPaint.setXfermodeMode(SkXfermode::kSrc_Mode);
for (int yTile = 0; yTile < (size.height()+15)/16; ++yTile) {
for (int xTile = 0; xTile < (size.width()+15)/16; ++xTile) {
int saveCount = tileCanvas.save();
SkMatrix mat(tileCanvas.getTotalMatrix());
mat.postTranslate(SkIntToScalar(-xTile*tileSize.width()),
SkIntToScalar(-yTile*tileSize.height()));
tileCanvas.setMatrix(mat);
pict->draw(&tileCanvas);
tileCanvas.flush();
tileCanvas.restoreToCount(saveCount);
bmpCanvas.drawBitmap(tileBM,
SkIntToScalar(xTile * tileSize.width()),
SkIntToScalar(yTile * tileSize.height()),
&bmpPaint);
}
}
} else {
SkCanvas canvas(*bitmap);
installFilter(&canvas);
canvas.scale(scale, scale);
canvas.drawPicture(pict);
complete_bitmap(bitmap);
}
}
static bool generate_pdf(GM* gm, SkDynamicMemoryWStream& pdf) {
#ifdef SK_SUPPORT_PDF
SkMatrix initialTransform = gm->getInitialTransform();
if (FLAGS_useDocumentInsteadOfDevice) {
SkISize pageISize = gm->getISize();
SkAutoTUnref<SkDocument> pdfDoc(
SkDocument::CreatePDF(&pdf, NULL,
encode_to_dct_data,
SkIntToScalar(FLAGS_pdfRasterDpi)));
if (!pdfDoc.get()) {
return false;
}
SkCanvas* canvas = NULL;
canvas = pdfDoc->beginPage(SkIntToScalar(pageISize.width()),
SkIntToScalar(pageISize.height()));
canvas->concat(initialTransform);
invokeGM(gm, canvas, true, false);
return pdfDoc->close();
} else {
SkISize pageSize = gm->getISize();
SkPDFDevice* dev = NULL;
if (initialTransform.isIdentity()) {
dev = new SkPDFDevice(pageSize, pageSize, initialTransform);
} else {
SkRect content = SkRect::MakeWH(SkIntToScalar(pageSize.width()),
SkIntToScalar(pageSize.height()));
initialTransform.mapRect(&content);
content.intersect(0, 0, SkIntToScalar(pageSize.width()),
SkIntToScalar(pageSize.height()));
SkISize contentSize =
SkISize::Make(SkScalarRoundToInt(content.width()),
SkScalarRoundToInt(content.height()));
dev = new SkPDFDevice(pageSize, contentSize, initialTransform);
}
dev->setDCTEncoder(encode_to_dct_data);
dev->setRasterDpi(SkIntToScalar(FLAGS_pdfRasterDpi));
SkAutoUnref aur(dev);
SkCanvas c(dev);
invokeGM(gm, &c, true, false);
SkPDFDocument doc;
doc.appendPage(dev);
doc.emitPDF(&pdf);
}
#endif // SK_SUPPORT_PDF
return true; // Do not report failure if pdf is not supported.
}
static void generate_xps(GM* gm, SkDynamicMemoryWStream& xps) {
#ifdef SK_SUPPORT_XPS
SkISize size = gm->getISize();
SkSize trimSize = SkSize::Make(SkIntToScalar(size.width()),
SkIntToScalar(size.height()));
static const SkScalar inchesPerMeter = SkScalarDiv(10000, 254);
static const SkScalar upm = 72 * inchesPerMeter;
SkVector unitsPerMeter = SkPoint::Make(upm, upm);
static const SkScalar ppm = 200 * inchesPerMeter;
SkVector pixelsPerMeter = SkPoint::Make(ppm, ppm);
SkXPSDevice* dev = new SkXPSDevice();
SkAutoUnref aur(dev);
SkCanvas c(dev);
dev->beginPortfolio(&xps);
dev->beginSheet(unitsPerMeter, pixelsPerMeter, trimSize);
invokeGM(gm, &c, false, false);
dev->endSheet();
dev->endPortfolio();
#endif
}
/**
* Log more detail about the mistmatch between expectedBitmap and
* actualBitmap.
*/
void report_bitmap_diffs(const SkBitmap& expectedBitmap, const SkBitmap& actualBitmap,
const char *testName) {
const int expectedWidth = expectedBitmap.width();
const int expectedHeight = expectedBitmap.height();
const int width = actualBitmap.width();
const int height = actualBitmap.height();
if ((expectedWidth != width) || (expectedHeight != height)) {
SkDebugf("---- %s: dimension mismatch -- expected [%d %d], actual [%d %d]\n",
testName, expectedWidth, expectedHeight, width, height);
return;
}
if ((kN32_SkColorType != expectedBitmap.colorType()) ||
(kN32_SkColorType != actualBitmap.colorType())) {
SkDebugf("---- %s: not computing max per-channel pixel mismatch because non-8888\n",
testName);
return;
}
SkAutoLockPixels alp0(expectedBitmap);
SkAutoLockPixels alp1(actualBitmap);
int errR = 0;
int errG = 0;
int errB = 0;
int errA = 0;
int differingPixels = 0;
for (int y = 0; y < height; ++y) {
const SkPMColor* expectedPixelPtr = expectedBitmap.getAddr32(0, y);
const SkPMColor* actualPixelPtr = actualBitmap.getAddr32(0, y);
for (int x = 0; x < width; ++x) {
SkPMColor expectedPixel = *expectedPixelPtr++;
SkPMColor actualPixel = *actualPixelPtr++;
if (expectedPixel != actualPixel) {
differingPixels++;
errR = SkMax32(errR, SkAbs32((int)SkGetPackedR32(expectedPixel) -
(int)SkGetPackedR32(actualPixel)));
errG = SkMax32(errG, SkAbs32((int)SkGetPackedG32(expectedPixel) -
(int)SkGetPackedG32(actualPixel)));
errB = SkMax32(errB, SkAbs32((int)SkGetPackedB32(expectedPixel) -
(int)SkGetPackedB32(actualPixel)));
errA = SkMax32(errA, SkAbs32((int)SkGetPackedA32(expectedPixel) -
(int)SkGetPackedA32(actualPixel)));
}
}
}
SkDebugf("---- %s: %d (of %d) differing pixels, "
"max per-channel mismatch R=%d G=%d B=%d A=%d\n",
testName, differingPixels, width*height, errR, errG, errB, errA);
}
/**
* Compares actual hash digest to expectations, returning the set of errors
* (if any) that we saw along the way.
*
* If fMismatchPath has been set, and there are pixel diffs, then the
* actual bitmap will be written out to a file within fMismatchPath.
* And similarly for fMissingExpectationsPath...
*
* @param expectations what expectations to compare actualBitmap against
* @param actualBitmapAndDigest the SkBitmap we actually generated, and its GmResultDigest
* @param shortName name of test, e.g. "selftest1"
* @param configName name of config, e.g. "8888"
* @param renderModeDescriptor e.g., "-rtree", "-deferred"
* @param addToJsonSummary whether to add these results (both actual and
* expected) to the JSON summary. Regardless of this setting, if
* we find an image mismatch in this test, we will write these
* results to the JSON summary. (This is so that we will always
* report errors across rendering modes, such as pipe vs tiled.
* See https://codereview.chromium.org/13650002/ )
*/
ErrorCombination compare_to_expectations(Expectations expectations,
const BitmapAndDigest& actualBitmapAndDigest,
const char *shortName, const char *configName,
const char *renderModeDescriptor,
bool addToJsonSummary) {
ErrorCombination errors;
SkString shortNamePlusConfig = make_shortname_plus_config(shortName, configName);
SkString completeNameString(shortNamePlusConfig);
completeNameString.append(renderModeDescriptor);
completeNameString.append(".");
completeNameString.append(kPNG_FileExtension);
const char* completeName = completeNameString.c_str();
if (expectations.empty()) {
errors.add(kMissingExpectations_ErrorType);
// Write out the "actuals" for any tests without expectations, if we have
// been directed to do so.
if (fMissingExpectationsPath) {
SkString path = make_bitmap_filename(fMissingExpectationsPath, shortName,
configName, renderModeDescriptor,
actualBitmapAndDigest.fDigest);
write_bitmap(path, actualBitmapAndDigest.fBitmap);
}
} else if (!expectations.match(actualBitmapAndDigest.fDigest)) {
addToJsonSummary = true;
// The error mode we record depends on whether this was running
// in a non-standard renderMode.
if ('\0' == *renderModeDescriptor) {
errors.add(kExpectationsMismatch_ErrorType);
} else {
errors.add(kRenderModeMismatch_ErrorType);
}
// Write out the "actuals" for any mismatches, if we have
// been directed to do so.
if (fMismatchPath) {
SkString path = make_bitmap_filename(fMismatchPath, shortName, configName,
renderModeDescriptor,
actualBitmapAndDigest.fDigest);
write_bitmap(path, actualBitmapAndDigest.fBitmap);
}
// If we have access to a single expected bitmap, log more
// detail about the mismatch.
const SkBitmap *expectedBitmapPtr = expectations.asBitmap();
if (NULL != expectedBitmapPtr) {
report_bitmap_diffs(*expectedBitmapPtr, actualBitmapAndDigest.fBitmap,
completeName);
}
}
if (addToJsonSummary) {
add_actual_results_to_json_summary(completeName, actualBitmapAndDigest.fDigest, errors,
expectations.ignoreFailure());
add_expected_results_to_json_summary(completeName, expectations);
}
return errors;
}
/**
* Add this result to the appropriate JSON collection of actual results (but just ONE),
* depending on errors encountered.
*/
void add_actual_results_to_json_summary(const char testName[],
const GmResultDigest &actualResultDigest,
ErrorCombination errors,
bool ignoreFailure) {
Json::Value jsonActualResults = actualResultDigest.asJsonTypeValuePair();
Json::Value *resultCollection = NULL;
if (errors.isEmpty()) {
resultCollection = &this->fJsonActualResults_Succeeded;
} else if (errors.includes(kRenderModeMismatch_ErrorType)) {
resultCollection = &this->fJsonActualResults_Failed;
} else if (errors.includes(kExpectationsMismatch_ErrorType)) {
if (ignoreFailure) {
resultCollection = &this->fJsonActualResults_FailureIgnored;
} else {
resultCollection = &this->fJsonActualResults_Failed;
}
} else if (errors.includes(kMissingExpectations_ErrorType)) {
// TODO: What about the case where there IS an expected
// image hash digest, but that gm test doesn't actually
// run? For now, those cases will always be ignored,
// because gm only looks at expectations that correspond
// to gm tests that were actually run.
//
// Once we have the ability to express expectations as a
// JSON file, we should fix this (and add a test case for
// which an expectation is given but the test is never
// run).
resultCollection = &this->fJsonActualResults_NoComparison;
}
// If none of the above cases match, we don't add it to ANY tally of actual results.
if (resultCollection) {
(*resultCollection)[testName] = jsonActualResults;
}
}
/**
* Add this test to the JSON collection of expected results.
*/
void add_expected_results_to_json_summary(const char testName[],
Expectations expectations) {
this->fJsonExpectedResults[testName] = expectations.asJsonValue();
}
/**
* Compare actualBitmap to expectations stored in this->fExpectationsSource.
*
* @param gm which test generated the actualBitmap
* @param gRec
* @param configName The config name to look for in the expectation file.
* @param actualBitmapAndDigest ptr to bitmap generated by this run, or NULL
* if we don't have a usable bitmap representation
*/
ErrorCombination compare_test_results_to_stored_expectations(
GM* gm, const ConfigData& gRec, const char* configName,
const BitmapAndDigest* actualBitmapAndDigest) {
ErrorCombination errors;
if (NULL == actualBitmapAndDigest) {
// Note that we intentionally skipped validating the results for
// this test, because we don't know how to generate an SkBitmap
// version of the output.
errors.add(ErrorCombination(kIntentionallySkipped_ErrorType));
} else if (!(gRec.fFlags & kWrite_ConfigFlag)) {
// We don't record the results for this test or compare them
// against any expectations, because the output image isn't
// meaningful.
// See https://code.google.com/p/skia/issues/detail?id=1410 ('some
// GM result images not available for download from Google Storage')
errors.add(ErrorCombination(kIntentionallySkipped_ErrorType));
} else {
ExpectationsSource *expectationsSource = this->fExpectationsSource.get();
SkString nameWithExtension = make_shortname_plus_config(gm->getName(), configName);
nameWithExtension.append(".");
nameWithExtension.append(kPNG_FileExtension);
if (expectationsSource && (gRec.fFlags & kRead_ConfigFlag)) {
/*
* Get the expected results for this test, as one or more allowed
* hash digests. The current implementation of expectationsSource
* get this by computing the hash digest of a single PNG file on disk.
*
* TODO(epoger): This relies on the fact that
* force_all_opaque() was called on the bitmap before it
* was written to disk as a PNG in the first place. If
* not, the hash digest returned here may not match the
* hash digest of actualBitmap, which *has* been run through
* force_all_opaque().
* See comments above complete_bitmap() for more detail.
*/
Expectations expectations = expectationsSource->get(nameWithExtension.c_str());
if (this->ShouldIgnoreTest(gm->getName())) {
expectations.setIgnoreFailure(true);
}
errors.add(compare_to_expectations(expectations, *actualBitmapAndDigest,
gm->getName(), configName, "", true));
} else {
// If we are running without expectations, we still want to
// record the actual results.
add_actual_results_to_json_summary(nameWithExtension.c_str(),
actualBitmapAndDigest->fDigest,
ErrorCombination(kMissingExpectations_ErrorType),
false);
errors.add(ErrorCombination(kMissingExpectations_ErrorType));
}
}
return errors;
}
/**
* Compare actualBitmap to referenceBitmap.
*
* @param shortName test name, e.g. "selftest1"
* @param configName configuration name, e.g. "8888"
* @param renderModeDescriptor
* @param actualBitmap actual bitmap generated by this run
* @param referenceBitmap bitmap we expected to be generated
*/
ErrorCombination compare_test_results_to_reference_bitmap(
const char *shortName, const char *configName, const char *renderModeDescriptor,
SkBitmap& actualBitmap, const SkBitmap* referenceBitmap) {
SkASSERT(referenceBitmap);
Expectations expectations(*referenceBitmap);
BitmapAndDigest actualBitmapAndDigest(actualBitmap);
// TODO: Eliminate RecordTestResults from here.
// Results recording code for the test_drawing path has been refactored so that
// RecordTestResults is only called once, at the topmost level. However, the
// other paths have not yet been refactored, and RecordTestResults has been added
// here to maintain proper behavior for calls not coming from the test_drawing path.
ErrorCombination errors;
errors.add(compare_to_expectations(expectations, actualBitmapAndDigest, shortName,
configName, renderModeDescriptor, false));
SkString shortNamePlusConfig = make_shortname_plus_config(shortName, configName);
RecordTestResults(errors, shortNamePlusConfig, renderModeDescriptor);
return errors;
}
static SkPicture* generate_new_picture(GM* gm, BbhType bbhType, uint32_t recordFlags,
SkScalar scale = SK_Scalar1) {
int width = SkScalarCeilToInt(SkScalarMul(SkIntToScalar(gm->getISize().width()), scale));
int height = SkScalarCeilToInt(SkScalarMul(SkIntToScalar(gm->getISize().height()), scale));
SkAutoTDelete<SkBBHFactory> factory;
if (kTileGrid_BbhType == bbhType) {
SkTileGridFactory::TileGridInfo info;
info.fMargin.setEmpty();
info.fOffset.setZero();
info.fTileInterval.set(16, 16);
factory.reset(SkNEW_ARGS(SkTileGridFactory, (info)));
} else if (kQuadTree_BbhType == bbhType) {
factory.reset(SkNEW(SkQuadTreeFactory));
} else if (kRTree_BbhType == bbhType) {
factory.reset(SkNEW(SkRTreeFactory));
}
SkPictureRecorder recorder;
SkCanvas* cv = recorder.beginRecording(width, height, factory.get(), recordFlags);
cv->scale(scale, scale);
invokeGM(gm, cv, false, false);
return recorder.endRecording();
}
static SkPicture* stream_to_new_picture(const SkPicture& src) {
SkDynamicMemoryWStream storage;
src.serialize(&storage, NULL);
SkAutoTUnref<SkStreamAsset> pictReadback(storage.detachAsStream());
SkPicture* retval = SkPicture::CreateFromStream(pictReadback,
&SkImageDecoder::DecodeMemory);
return retval;
}
// Test: draw into a bitmap or pdf.
// Depending on flags, possibly compare to an expected image.
// If writePath is not NULL, also write images (or documents) to the specified path.
ErrorCombination test_drawing(GM* gm, const ConfigData& gRec,
const SkTDArray<const PDFRasterizerData*> &pdfRasterizers,
const char writePath [],
GrSurface* gpuTarget,
SkBitmap* bitmap) {
ErrorCombination errors;
SkDynamicMemoryWStream document;
SkString path;
if (gRec.fBackend == kRaster_Backend ||
gRec.fBackend == kGPU_Backend) {
// Early exit if we can't generate the image.
errors.add(generate_image(gm, gRec, gpuTarget, bitmap, false));
if (!errors.isEmpty()) {
// TODO: Add a test to exercise what the stdout and
// JSON look like if we get an "early error" while
// trying to generate the image.
return errors;
}
BitmapAndDigest bitmapAndDigest(*bitmap);
errors.add(compare_test_results_to_stored_expectations(
gm, gRec, gRec.fName, &bitmapAndDigest));
if (writePath && (gRec.fFlags & kWrite_ConfigFlag)) {
path = make_bitmap_filename(writePath, gm->getName(), gRec.fName,
"", bitmapAndDigest.fDigest);
errors.add(write_bitmap(path, bitmapAndDigest.fBitmap));
}
} else if (gRec.fBackend == kPDF_Backend) {
if (!generate_pdf(gm, document)) {
errors.add(kGeneratePdfFailed_ErrorType);
} else {
SkAutoTUnref<SkStreamAsset> documentStream(document.detachAsStream());
if (writePath && (gRec.fFlags & kWrite_ConfigFlag)) {
path = make_filename(writePath, gm->getName(), gRec.fName, "", "pdf");
errors.add(write_document(path, documentStream));
}
if (!(gm->getFlags() & GM::kSkipPDFRasterization_Flag)) {
for (int i = 0; i < pdfRasterizers.count(); i++) {
SkBitmap pdfBitmap;
documentStream->rewind();
bool success = (*pdfRasterizers[i]->fRasterizerFunction)(
documentStream.get(), &pdfBitmap);
if (!success) {
SkDebugf("FAILED to render PDF for %s using renderer %s\n",
gm->getName(),
pdfRasterizers[i]->fName);
continue;
}
SkString configName(gRec.fName);
configName.append("-");
configName.append(pdfRasterizers[i]->fName);
BitmapAndDigest bitmapAndDigest(pdfBitmap);
errors.add(compare_test_results_to_stored_expectations(
gm, gRec, configName.c_str(), &bitmapAndDigest));
if (writePath && (gRec.fFlags & kWrite_ConfigFlag)) {
path = make_bitmap_filename(writePath, gm->getName(),
configName.c_str(),
"", bitmapAndDigest.fDigest);
errors.add(write_bitmap(path, bitmapAndDigest.fBitmap));
}
}
} else {
errors.add(kIntentionallySkipped_ErrorType);
}
}
} else if (gRec.fBackend == kXPS_Backend) {
generate_xps(gm, document);
SkAutoTUnref<SkStreamAsset> documentStream(document.detachAsStream());
errors.add(compare_test_results_to_stored_expectations(
gm, gRec, gRec.fName, NULL));
if (writePath && (gRec.fFlags & kWrite_ConfigFlag)) {
path = make_filename(writePath, gm->getName(), gRec.fName, "", "xps");
errors.add(write_document(path, documentStream));
}
} else {
SkASSERT(false);
}
return errors;
}
ErrorCombination test_deferred_drawing(GM* gm,
const ConfigData& gRec,
const SkBitmap& referenceBitmap,
GrSurface* gpuTarget) {
if (gRec.fBackend == kRaster_Backend ||
gRec.fBackend == kGPU_Backend) {
const char renderModeDescriptor[] = "-deferred";
SkBitmap bitmap;
// Early exit if we can't generate the image, but this is
// expected in some cases, so don't report a test failure.
ErrorCombination errors = generate_image(gm, gRec, gpuTarget, &bitmap, true);
// TODO(epoger): This logic is the opposite of what is
// described above... if we succeeded in generating the
// -deferred image, we exit early! We should fix this
// ASAP, because it is hiding -deferred errors... but for
// now, I'm leaving the logic as it is so that the
// refactoring change
// https://codereview.chromium.org/12992003/ is unblocked.
//
// Filed as https://code.google.com/p/skia/issues/detail?id=1180
// ('image-surface gm test is failing in "deferred" mode,
// and gm is not reporting the failure')
if (errors.isEmpty()) {
// TODO(epoger): Report this as a new ErrorType,
// something like kImageGeneration_ErrorType?
return kEmpty_ErrorCombination;
}
return compare_test_results_to_reference_bitmap(
gm->getName(), gRec.fName, renderModeDescriptor, bitmap, &referenceBitmap);
}
return kEmpty_ErrorCombination;
}
ErrorCombination test_pipe_playback(GM* gm, const ConfigData& gRec,
const SkBitmap& referenceBitmap, bool simulateFailure) {
const SkString shortNamePlusConfig = make_shortname_plus_config(gm->getName(),
gRec.fName);
ErrorCombination errors;
for (size_t i = 0; i < SK_ARRAY_COUNT(gPipeWritingFlagCombos); ++i) {
SkString renderModeDescriptor("-pipe");
renderModeDescriptor.append(gPipeWritingFlagCombos[i].name);
if (gm->getFlags() & GM::kSkipPipe_Flag
|| (gPipeWritingFlagCombos[i].flags == SkGPipeWriter::kCrossProcess_Flag
&& gm->getFlags() & GM::kSkipPipeCrossProcess_Flag)) {
RecordTestResults(kIntentionallySkipped_ErrorType, shortNamePlusConfig,
renderModeDescriptor.c_str());
errors.add(kIntentionallySkipped_ErrorType);
} else {
SkBitmap bitmap;
SkISize size = gm->getISize();
setup_bitmap(gRec, size, &bitmap);
SkCanvas canvas(bitmap);
installFilter(&canvas);
// Pass a decoding function so the factory GM (which has an SkBitmap
// with encoded data) will not fail playback.
PipeController pipeController(&canvas, &SkImageDecoder::DecodeMemory);
SkGPipeWriter writer;
SkCanvas* pipeCanvas = writer.startRecording(&pipeController,
gPipeWritingFlagCombos[i].flags,
size.width(), size.height());
if (!simulateFailure) {
invokeGM(gm, pipeCanvas, false, false);
}
complete_bitmap(&bitmap);
writer.endRecording();
errors.add(compare_test_results_to_reference_bitmap(
gm->getName(), gRec.fName, renderModeDescriptor.c_str(), bitmap,
&referenceBitmap));
if (!errors.isEmpty()) {
break;
}
}
}
return errors;
}
ErrorCombination test_tiled_pipe_playback(GM* gm, const ConfigData& gRec,
const SkBitmap& referenceBitmap) {
const SkString shortNamePlusConfig = make_shortname_plus_config(gm->getName(),
gRec.fName);
ErrorCombination errors;
for (size_t i = 0; i < SK_ARRAY_COUNT(gPipeWritingFlagCombos); ++i) {
SkString renderModeDescriptor("-tiled pipe");
renderModeDescriptor.append(gPipeWritingFlagCombos[i].name);
if ((gm->getFlags() & GM::kSkipPipe_Flag) ||
(gm->getFlags() & GM::kSkipTiled_Flag)) {
RecordTestResults(kIntentionallySkipped_ErrorType, shortNamePlusConfig,
renderModeDescriptor.c_str());
errors.add(kIntentionallySkipped_ErrorType);
} else {
SkBitmap bitmap;
SkISize size = gm->getISize();
setup_bitmap(gRec, size, &bitmap);
SkCanvas canvas(bitmap);
installFilter(&canvas);
TiledPipeController pipeController(bitmap, &SkImageDecoder::DecodeMemory);
SkGPipeWriter writer;
SkCanvas* pipeCanvas = writer.startRecording(&pipeController,
gPipeWritingFlagCombos[i].flags,
size.width(), size.height());
invokeGM(gm, pipeCanvas, false, false);
complete_bitmap(&bitmap);
writer.endRecording();
errors.add(compare_test_results_to_reference_bitmap(gm->getName(), gRec.fName,
renderModeDescriptor.c_str(),
bitmap, &referenceBitmap));
if (!errors.isEmpty()) {
break;
}
}
}
return errors;
}
//
// member variables.
// They are public for now, to allow easier setting by tool_main().
//
bool fUseFileHierarchy, fWriteChecksumBasedFilenames;
ErrorCombination fIgnorableErrorTypes;
SkTArray<SkString> fIgnorableTestNames;
const char* fMismatchPath;
const char* fMissingExpectationsPath;
// collection of tests that have failed with each ErrorType
SkTArray<SkString> fFailedTests[kLast_ErrorType+1];
SkTArray<SkString> fTestsSkippedOnAllRenderModes;
int fTestsRun;
SkTDict<int> fRenderModesEncountered;
// Where to read expectations (expected image hash digests, etc.) from.
// If unset, we don't do comparisons.
SkAutoTUnref<ExpectationsSource> fExpectationsSource;
// JSON summaries that we generate as we go (just for output).
Json::Value fJsonExpectedResults;
Json::Value fJsonActualResults_Failed;
Json::Value fJsonActualResults_FailureIgnored;
Json::Value fJsonActualResults_NoComparison;
Json::Value fJsonActualResults_Succeeded;
}; // end of GMMain class definition
#if SK_SUPPORT_GPU
static const GLContextType kDontCare_GLContextType = GrContextFactory::kNative_GLContextType;
#else
static const GLContextType kDontCare_GLContextType = 0;
#endif
static const ConfigData gRec[] = {
{ kN32_SkColorType, kRaster_Backend, kDontCare_GLContextType, 0, kRW_ConfigFlag, "8888", true },
{ kRGB_565_SkColorType, kRaster_Backend, kDontCare_GLContextType, 0, kRW_ConfigFlag, "565", true },
#if SK_SUPPORT_GPU
{ kN32_SkColorType, kGPU_Backend, GrContextFactory::kNative_GLContextType, 0, kRW_ConfigFlag, "gpu", true },
{ kN32_SkColorType, kGPU_Backend, GrContextFactory::kNative_GLContextType, 16, kRW_ConfigFlag, "msaa16", false},
{ kN32_SkColorType, kGPU_Backend, GrContextFactory::kNative_GLContextType, 4, kRW_ConfigFlag, "msaa4", false},
{ kN32_SkColorType, kGPU_Backend, GrContextFactory::kNVPR_GLContextType, 4, kRW_ConfigFlag, "nvprmsaa4", true },
{ kN32_SkColorType, kGPU_Backend, GrContextFactory::kNVPR_GLContextType, 16, kRW_ConfigFlag, "nvprmsaa16", false},
/* The gpudebug context does not generate meaningful images, so don't record
* the images it generates! We only run it to look for asserts. */
{ kN32_SkColorType, kGPU_Backend, GrContextFactory::kDebug_GLContextType, 0, kNone_ConfigFlag, "gpudebug", kDebugOnly},
/* The gpunull context does the least amount of work possible and doesn't
generate meaninful images, so don't record them!. It can be run to
isolate the CPU-side processing expense from the GPU-side.
*/
{ kN32_SkColorType, kGPU_Backend, GrContextFactory::kNull_GLContextType, 0, kNone_ConfigFlag, "gpunull", kDebugOnly},
#if SK_ANGLE
{ kN32_SkColorType, kGPU_Backend, GrContextFactory::kANGLE_GLContextType, 0, kRW_ConfigFlag, "angle", true },
{ kN32_SkColorType, kGPU_Backend, GrContextFactory::kANGLE_GLContextType, 16, kRW_ConfigFlag, "anglemsaa16", true },
#endif // SK_ANGLE
#ifdef SK_MESA
{ kN32_SkColorType, kGPU_Backend, GrContextFactory::kMESA_GLContextType, 0, kRW_ConfigFlag, "mesa", true },
#endif // SK_MESA
#endif // SK_SUPPORT_GPU
#ifdef SK_SUPPORT_XPS
/* At present we have no way of comparing XPS files (either natively or by converting to PNG). */
{ kN32_SkColorType, kXPS_Backend, kDontCare_GLContextType, 0, kWrite_ConfigFlag, "xps", true },
#endif // SK_SUPPORT_XPS
#ifdef SK_SUPPORT_PDF
{ kN32_SkColorType, kPDF_Backend, kDontCare_GLContextType, 0, kRW_ConfigFlag, "pdf", true },
#endif // SK_SUPPORT_PDF
};
static bool SkNoRasterizePDF(SkStream*, SkBitmap*) { return false; }
static const PDFRasterizerData kPDFRasterizers[] = {
#ifdef SK_BUILD_FOR_MAC
{ &SkPDFDocumentToBitmap, "mac", true },
#endif
#ifdef SK_BUILD_POPPLER
{ &SkPopplerRasterizePDF, "poppler", true },
#endif
#ifdef SK_BUILD_NATIVE_PDF_RENDERER
{ &SkNativeRasterizePDF, "native", true },
#endif // SK_BUILD_NATIVE_PDF_RENDERER
// The following exists so that this array is never zero length.
{ &SkNoRasterizePDF, "none", false},
};
static const char kDefaultsConfigStr[] = "defaults";
static const char kExcludeConfigChar = '~';
static SkString configUsage() {
SkString result;
result.appendf("Space delimited list of which configs to run. Possible options: [");
for (size_t i = 0; i < SK_ARRAY_COUNT(gRec); ++i) {
SkASSERT(gRec[i].fName != kDefaultsConfigStr);
if (i > 0) {
result.append("|");
}
result.appendf("%s", gRec[i].fName);
}
result.append("]\n");
result.appendf("The default value is: \"");
SkString firstDefault;
SkString allButFirstDefaults;
SkString nonDefault;
for (size_t i = 0; i < SK_ARRAY_COUNT(gRec); ++i) {
if (gRec[i].fRunByDefault) {
if (i > 0) {
result.append(" ");
}
result.append(gRec[i].fName);
if (firstDefault.isEmpty()) {
firstDefault = gRec[i].fName;
} else {
if (!allButFirstDefaults.isEmpty()) {
allButFirstDefaults.append(" ");
}
allButFirstDefaults.append(gRec[i].fName);
}
} else {
nonDefault = gRec[i].fName;
}
}
result.append("\"\n");
result.appendf("\"%s\" evaluates to the default set of configs.\n", kDefaultsConfigStr);
result.appendf("Prepending \"%c\" on a config name excludes it from the set of configs to run.\n"
"Exclusions always override inclusions regardless of order.\n",
kExcludeConfigChar);
result.appendf("E.g. \"--config %s %c%s %s\" will run these configs:\n\t%s %s",
kDefaultsConfigStr,
kExcludeConfigChar,
firstDefault.c_str(),
nonDefault.c_str(),
allButFirstDefaults.c_str(),
nonDefault.c_str());
return result;
}
static SkString pdfRasterizerUsage() {
SkString result;
result.appendf("Space delimited list of which PDF rasterizers to run. Possible options: [");
// For this (and further) loops through kPDFRasterizers, there is a typecast to int to avoid
// the compiler giving an "comparison of unsigned expression < 0 is always false" warning
// and turning it into a build-breaking error.
for (int i = 0; i < (int)SK_ARRAY_COUNT(kPDFRasterizers); ++i) {
if (i > 0) {
result.append(" ");
}
result.append(kPDFRasterizers[i].fName);
}
result.append("]\n");
result.append("The default value is: \"");
for (int i = 0; i < (int)SK_ARRAY_COUNT(kPDFRasterizers); ++i) {
if (kPDFRasterizers[i].fRunByDefault) {
if (i > 0) {
result.append(" ");
}
result.append(kPDFRasterizers[i].fName);
}
}
result.append("\"");
return result;
}
// Macro magic to convert a numeric preprocessor token into a string.
// Adapted from http://stackoverflow.com/questions/240353/convert-a-preprocessor-token-to-a-string
// This should probably be moved into one of our common headers...
#define TOSTRING_INTERNAL(x) #x
#define TOSTRING(x) TOSTRING_INTERNAL(x)
// Alphabetized ignoring "no" prefix ("readPath", "noreplay", "resourcePath").
DEFINE_string(config, "", configUsage().c_str());
DEFINE_string(pdfRasterizers, "default", pdfRasterizerUsage().c_str());
DEFINE_bool(deferred, false, "Exercise the deferred rendering test pass.");
DEFINE_bool(dryRun, false, "Don't actually run the tests, just print what would have been done.");
DEFINE_string(excludeConfig, "", "Space delimited list of configs to skip.");
DEFINE_bool(forceBWtext, false, "Disable text anti-aliasing.");
#if SK_SUPPORT_GPU
DEFINE_string(gpuCacheSize, "", "<bytes> <count>: Limit the gpu cache to byte size or "
"object count. " TOSTRING(DEFAULT_CACHE_VALUE) " for either value means "
"use the default. 0 for either disables the cache.");
#endif
DEFINE_bool(hierarchy, false, "Whether to use multilevel directory structure "
"when reading/writing files.");
DEFINE_string(ignoreErrorTypes, kDefaultIgnorableErrorTypes.asString(" ").c_str(),
"Space-separated list of ErrorTypes that should be ignored. If any *other* error "
"types are encountered, the tool will exit with a nonzero return value.");
DEFINE_string(ignoreFailuresFile, "", "Path to file containing a list of tests for which we "
"should ignore failures.\n"
"The file should list one test per line, except for comment lines starting with #");
DEFINE_bool2(leaks, l, false, "show leaked ref cnt'd objects.");
DEFINE_string(match, "", "[~][^]substring[$] [...] of test name to run.\n"
"Multiple matches may be separated by spaces.\n"
"~ causes a matching test to always be skipped\n"
"^ requires the start of the test to match\n"
"$ requires the end of the test to match\n"
"^ and $ requires an exact match\n"
"If a test does not match any list entry,\n"
"it is skipped unless some list entry starts with ~");
DEFINE_string(missingExpectationsPath, "", "Write images for tests without expectations "
"into this directory.");
DEFINE_string(mismatchPath, "", "Write images for tests that failed due to "
"pixel mismatches into this directory.");
DEFINE_string(modulo, "", "[--modulo <remainder> <divisor>]: only run tests for which "
"testIndex %% divisor == remainder.");
DEFINE_bool(pipe, false, "Exercise the SkGPipe replay test pass.");
DEFINE_bool(quadtree, false, "Exercise the QuadTree variant of SkPicture test pass.");
DEFINE_string2(readPath, r, "", "Read reference images from this dir, and report "
"any differences between those and the newly generated ones.");
DEFINE_bool(replay, false, "Exercise the SkPicture replay test pass.");
#if SK_SUPPORT_GPU
DEFINE_bool(resetGpuContext, false, "Reset the GrContext prior to running each GM.");
#endif
DEFINE_bool(rtree, false, "Exercise the R-Tree variant of SkPicture test pass.");
DEFINE_bool(serialize, false, "Exercise the SkPicture serialization & deserialization test pass.");
DEFINE_bool(simulatePipePlaybackFailure, false, "Simulate a rendering failure in pipe mode only.");
DEFINE_bool(tiledPipe, false, "Exercise tiled SkGPipe replay.");
DEFINE_bool(tileGrid, false, "Exercise the tile grid variant of SkPicture.");
DEFINE_string(tileGridReplayScales, "", "Space separated list of floating-point scale "
"factors to be used for tileGrid playback testing. Default value: 1.0");
DEFINE_bool2(verbose, v, false, "Give more detail (e.g. list all GMs run, more info about "
"each test).");
DEFINE_bool(writeChecksumBasedFilenames, false, "When writing out actual images, use checksum-"
"based filenames, as rebaseline.py will use when downloading them from Google Storage");
DEFINE_string(writeJsonSummaryPath, "", "Write a JSON-formatted result summary to this file.");
DEFINE_string2(writePath, w, "", "Write rendered images into this directory.");
DEFINE_string2(writePicturePath, p, "", "Write .skp files into this directory.");
DEFINE_int32(pdfJpegQuality, -1, "Encodes images in JPEG at quality level N, "
"which can be in range 0-100). N = -1 will disable JPEG compression. "
"Default is N = 100, maximum quality.");
// TODO(edisonn): pass a matrix instead of forcePerspectiveMatrix
// Either the 9 numbers defining the matrix
// or probably more readable would be to replace it with a set of a few predicates
// Like --prerotate 100 200 10 --posttranslate 10, 10
// Probably define spacial names like centerx, centery, top, bottom, left, right
// then we can write something reabable like --rotate centerx centery 90
DEFINE_bool(forcePerspectiveMatrix, false, "Force a perspective matrix.");
DEFINE_bool(useDocumentInsteadOfDevice, false, "Use SkDocument::CreateFoo instead of SkFooDevice.");
DEFINE_int32(pdfRasterDpi, 72, "Scale at which at which the non suported "
"features in PDF are rasterized. Must be be in range 0-10000. "
"Default is 72. N = 0 will disable rasterizing features like "
"text shadows or perspective bitmaps.");
static SkData* encode_to_dct_data(size_t*, const SkBitmap& bitmap) {
// Filter output of warnings that JPEG is not available for the image.
if (bitmap.width() >= 65500 || bitmap.height() >= 65500) return NULL;
if (FLAGS_pdfJpegQuality == -1) return NULL;
SkBitmap bm = bitmap;
#if defined(SK_BUILD_FOR_MAC)
// Workaround bug #1043 where bitmaps with referenced pixels cause
// CGImageDestinationFinalize to crash
SkBitmap copy;
bitmap.deepCopyTo(&copy);
bm = copy;
#endif
SkPixelRef* pr = bm.pixelRef();
if (pr != NULL) {
SkData* data = pr->refEncodedData();
if (data != NULL) {
return data;
}
}
return SkImageEncoder::EncodeData(bm,
SkImageEncoder::kJPEG_Type,
FLAGS_pdfJpegQuality);
}
static int findConfig(const char config[]) {
for (size_t i = 0; i < SK_ARRAY_COUNT(gRec); i++) {
if (!strcmp(config, gRec[i].fName)) {
return (int) i;
}
}
return -1;
}
static const PDFRasterizerData* findPDFRasterizer(const char rasterizer[]) {
for (int i = 0; i < (int)SK_ARRAY_COUNT(kPDFRasterizers); i++) {
if (!strcmp(rasterizer, kPDFRasterizers[i].fName)) {
return &kPDFRasterizers[i];
}
}
return NULL;
}
template <typename T> void appendUnique(SkTDArray<T>* array, const T& value) {
int index = array->find(value);
if (index < 0) {
*array->append() = value;
}
}
/**
* Run this test in a number of different drawing modes (pipe,
* deferred, tiled, etc.), confirming that the resulting bitmaps all
* *exactly* match comparisonBitmap.
*
* Returns all errors encountered while doing so.
*/
ErrorCombination run_multiple_modes(GMMain &gmmain, GM *gm, const ConfigData &compareConfig,
const SkBitmap &comparisonBitmap,
const SkTDArray<SkScalar> &tileGridReplayScales);
ErrorCombination run_multiple_modes(GMMain &gmmain, GM *gm, const ConfigData &compareConfig,
const SkBitmap &comparisonBitmap,
const SkTDArray<SkScalar> &tileGridReplayScales) {
ErrorCombination errorsForAllModes;
uint32_t gmFlags = gm->getFlags();
const SkString shortNamePlusConfig = gmmain.make_shortname_plus_config(gm->getName(),
compareConfig.fName);
SkPicture* pict = gmmain.generate_new_picture(gm, kNone_BbhType, 0);
SkAutoUnref aur(pict);
if (FLAGS_replay) {
const char renderModeDescriptor[] = "-replay";
if (gmFlags & GM::kSkipPicture_Flag) {
gmmain.RecordTestResults(kIntentionallySkipped_ErrorType, shortNamePlusConfig,
renderModeDescriptor);
errorsForAllModes.add(kIntentionallySkipped_ErrorType);
} else {
SkBitmap bitmap;
gmmain.generate_image_from_picture(gm, compareConfig, pict, &bitmap);
errorsForAllModes.add(gmmain.compare_test_results_to_reference_bitmap(
gm->getName(), compareConfig.fName, renderModeDescriptor, bitmap,
&comparisonBitmap));
}
}
if (FLAGS_serialize) {
const char renderModeDescriptor[] = "-serialize";
if (gmFlags & GM::kSkipPicture_Flag) {
gmmain.RecordTestResults(kIntentionallySkipped_ErrorType, shortNamePlusConfig,
renderModeDescriptor);
errorsForAllModes.add(kIntentionallySkipped_ErrorType);
} else {
SkPicture* repict = gmmain.stream_to_new_picture(*pict);
SkAutoUnref aurr(repict);
SkBitmap bitmap;
gmmain.generate_image_from_picture(gm, compareConfig, repict, &bitmap);
errorsForAllModes.add(gmmain.compare_test_results_to_reference_bitmap(
gm->getName(), compareConfig.fName, renderModeDescriptor, bitmap,
&comparisonBitmap));
}
}
if ((1 == FLAGS_writePicturePath.count()) &&
!(gmFlags & GM::kSkipPicture_Flag)) {
const char* pictureSuffix = "skp";
// TODO(epoger): Make sure this still works even though the
// filename now contains the config name (it used to contain
// just the shortName). I think this is actually an
// *improvement*, because now runs with different configs will
// write out their SkPictures to separate files rather than
// overwriting each other. But we should make sure it doesn't
// break anybody.
SkString path = gmmain.make_filename(FLAGS_writePicturePath[0], gm->getName(),
compareConfig.fName, "", pictureSuffix);
SkFILEWStream stream(path.c_str());
pict->serialize(&stream);
}
if (FLAGS_rtree) {
const char renderModeDescriptor[] = "-rtree";
if ((gmFlags & GM::kSkipPicture_Flag) || (gmFlags & GM::kSkipTiled_Flag)) {
gmmain.RecordTestResults(kIntentionallySkipped_ErrorType, shortNamePlusConfig,
renderModeDescriptor);
errorsForAllModes.add(kIntentionallySkipped_ErrorType);
} else {
SkPicture* pict = gmmain.generate_new_picture(gm, kRTree_BbhType, 0);
SkAutoUnref aur(pict);
SkBitmap bitmap;
gmmain.generate_image_from_picture(gm, compareConfig, pict, &bitmap);
errorsForAllModes.add(gmmain.compare_test_results_to_reference_bitmap(
gm->getName(), compareConfig.fName, renderModeDescriptor, bitmap,
&comparisonBitmap));
}
}
if (FLAGS_quadtree) {
const char renderModeDescriptor[] = "-quadtree";
if ((gmFlags & GM::kSkipPicture_Flag) || (gmFlags & GM::kSkipTiled_Flag)) {
gmmain.RecordTestResults(kIntentionallySkipped_ErrorType, shortNamePlusConfig,
renderModeDescriptor);
errorsForAllModes.add(kIntentionallySkipped_ErrorType);
} else {
SkPicture* pict = gmmain.generate_new_picture(gm, kQuadTree_BbhType, 0);
SkAutoUnref aur(pict);
SkBitmap bitmap;
gmmain.generate_image_from_picture(gm, compareConfig, pict, &bitmap);
errorsForAllModes.add(gmmain.compare_test_results_to_reference_bitmap(
gm->getName(), compareConfig.fName, renderModeDescriptor, bitmap,
&comparisonBitmap));
}
}
if (FLAGS_tileGrid) {
for(int scaleIndex = 0; scaleIndex < tileGridReplayScales.count(); ++scaleIndex) {
SkScalar replayScale = tileGridReplayScales[scaleIndex];
SkString renderModeDescriptor("-tilegrid");
if (SK_Scalar1 != replayScale) {
renderModeDescriptor += "-scale-";
renderModeDescriptor.appendScalar(replayScale);
}
if ((gmFlags & GM::kSkipPicture_Flag) ||
(gmFlags & GM::kSkipTiled_Flag) ||
((gmFlags & GM::kSkipScaledReplay_Flag) && replayScale != 1)) {
gmmain.RecordTestResults(kIntentionallySkipped_ErrorType, shortNamePlusConfig,
renderModeDescriptor.c_str());
errorsForAllModes.add(kIntentionallySkipped_ErrorType);
} else {
// We record with the reciprocal scale to obtain a replay
// result that can be validated against comparisonBitmap.
SkScalar recordScale = SkScalarInvert(replayScale);
SkPicture* pict = gmmain.generate_new_picture(
gm, kTileGrid_BbhType, 0, recordScale);
SkAutoUnref aur(pict);
SkBitmap bitmap;
// We cannot yet pass 'true' to generate_image_from_picture to
// perform actual tiled rendering (see Issue 1198 -
// https://code.google.com/p/skia/issues/detail?id=1198)
gmmain.generate_image_from_picture(gm, compareConfig, pict, &bitmap,
replayScale /*, true */);
errorsForAllModes.add(gmmain.compare_test_results_to_reference_bitmap(
gm->getName(), compareConfig.fName, renderModeDescriptor.c_str(), bitmap,
&comparisonBitmap));
}
}
}
// run the pipe centric GM steps
if (FLAGS_pipe) {
errorsForAllModes.add(gmmain.test_pipe_playback(gm, compareConfig, comparisonBitmap,
FLAGS_simulatePipePlaybackFailure));
if (FLAGS_tiledPipe) {
errorsForAllModes.add(gmmain.test_tiled_pipe_playback(gm, compareConfig,
comparisonBitmap));
}
}
return errorsForAllModes;
}
/**
* Run this test in a number of different configs (8888, 565, PDF,
* etc.), confirming that the resulting bitmaps match expectations
* (which may be different for each config).
*
* Returns all errors encountered while doing so.
*/
ErrorCombination run_multiple_configs(GMMain &gmmain, GM *gm,
const SkTDArray<size_t> &configs,
const SkTDArray<const PDFRasterizerData*> &pdfRasterizers,
const SkTDArray<SkScalar> &tileGridReplayScales,
GrContextFactory *grFactory);
ErrorCombination run_multiple_configs(GMMain &gmmain, GM *gm,
const SkTDArray<size_t> &configs,
const SkTDArray<const PDFRasterizerData*> &pdfRasterizers,
const SkTDArray<SkScalar> &tileGridReplayScales,
GrContextFactory *grFactory) {
const char renderModeDescriptor[] = "";
ErrorCombination errorsForAllConfigs;
uint32_t gmFlags = gm->getFlags();
for (int i = 0; i < configs.count(); i++) {
ConfigData config = gRec[configs[i]];
const SkString shortNamePlusConfig = gmmain.make_shortname_plus_config(gm->getName(),
config.fName);
// Skip any tests that we don't even need to try.
// If any of these were skipped on a per-GM basis, record them as
// kIntentionallySkipped.
if (kPDF_Backend == config.fBackend) {
if (gmFlags & GM::kSkipPDF_Flag) {
gmmain.RecordSkippedTest(shortNamePlusConfig,
renderModeDescriptor,
config.fBackend);
errorsForAllConfigs.add(kIntentionallySkipped_ErrorType);
continue;
}
}
if ((gmFlags & GM::kSkip565_Flag) &&
(kRaster_Backend == config.fBackend) &&
(kRGB_565_SkColorType == config.fColorType)) {
gmmain.RecordSkippedTest(shortNamePlusConfig,
renderModeDescriptor,
config.fBackend);
errorsForAllConfigs.add(kIntentionallySkipped_ErrorType);
continue;
}
if (((gmFlags & GM::kSkipGPU_Flag) && kGPU_Backend == config.fBackend) ||
((gmFlags & GM::kGPUOnly_Flag) && kGPU_Backend != config.fBackend)) {
gmmain.RecordSkippedTest(shortNamePlusConfig,
renderModeDescriptor,
config.fBackend);
errorsForAllConfigs.add(kIntentionallySkipped_ErrorType);
continue;
}
// Now we know that we want to run this test and record its
// success or failure.
ErrorCombination errorsForThisConfig;
GrSurface* gpuTarget = NULL;
#if SK_SUPPORT_GPU
SkAutoTUnref<GrSurface> auGpuTarget;
if ((errorsForThisConfig.isEmpty()) && (kGPU_Backend == config.fBackend)) {
if (FLAGS_resetGpuContext) {
grFactory->destroyContexts();
}
GrContext* gr = grFactory->get(config.fGLContextType);
bool grSuccess = false;
if (gr) {
// create a render target to back the device
GrTextureDesc desc;
desc.fConfig = kSkia8888_GrPixelConfig;
desc.fFlags = kRenderTarget_GrTextureFlagBit;
desc.fWidth = gm->getISize().width();
desc.fHeight = gm->getISize().height();
desc.fSampleCnt = config.fSampleCnt;
auGpuTarget.reset(gr->createUncachedTexture(desc, NULL, 0));
if (NULL != auGpuTarget) {
gpuTarget = auGpuTarget;
grSuccess = true;
// Set the user specified cache limits if non-default.
size_t bytes;
int count;
gr->getResourceCacheLimits(&count, &bytes);
if (DEFAULT_CACHE_VALUE != gGpuCacheSizeBytes) {
bytes = static_cast<size_t>(gGpuCacheSizeBytes);
}
if (DEFAULT_CACHE_VALUE != gGpuCacheSizeCount) {
count = gGpuCacheSizeCount;
}
gr->setResourceCacheLimits(count, bytes);
}
}
if (!grSuccess) {
errorsForThisConfig.add(kNoGpuContext_ErrorType);
}
}
#endif
SkBitmap comparisonBitmap;
const char* writePath;
if (FLAGS_writePath.count() == 1) {
writePath = FLAGS_writePath[0];
} else {
writePath = NULL;
}
if (errorsForThisConfig.isEmpty()) {
errorsForThisConfig.add(gmmain.test_drawing(gm, config, pdfRasterizers,
writePath, gpuTarget,
&comparisonBitmap));
gmmain.RecordTestResults(errorsForThisConfig, shortNamePlusConfig, "");
}
// TODO: run only if gmmain.test_drawing succeeded.
if (kRaster_Backend == config.fBackend) {
run_multiple_modes(gmmain, gm, config, comparisonBitmap, tileGridReplayScales);
}
if (FLAGS_deferred && errorsForThisConfig.isEmpty() &&
(kGPU_Backend == config.fBackend || kRaster_Backend == config.fBackend)) {
errorsForThisConfig.add(gmmain.test_deferred_drawing(gm, config, comparisonBitmap,
gpuTarget));
}
errorsForAllConfigs.add(errorsForThisConfig);
}
return errorsForAllConfigs;
}
/**
* Read individual lines from a file, pushing them into the given array.
*
* @param filename path to the file to read
* @param lines array of strings to add the lines to
* @returns true if able to read lines from the file
*/
static bool read_lines_from_file(const char* filename, SkTArray<SkString> &lines) {
SkAutoTUnref<SkStream> streamWrapper(SkStream::NewFromFile(filename));
SkStream *stream = streamWrapper.get();
if (!stream) {
SkDebugf("unable to read file '%s'\n", filename);
return false;
}
char c;
SkString line;
while (1 == stream->read(&c, 1)) {
// If we hit either CR or LF, we've completed a line.
//
// TODO: If the file uses both CR and LF, this will return an extra blank
// line for each line of the file. Which is OK for current purposes...
//
// TODO: Does this properly handle unicode? It doesn't matter for
// current purposes...
if ((c == 0x0d) || (c == 0x0a)) {
lines.push_back(line);
line.reset();
} else {
line.append(&c, 1);
}
}
lines.push_back(line);
return true;
}
/**
* Return a list of all entries in an array of strings as a single string
* of this form:
* "item1", "item2", "item3"
*/
SkString list_all(const SkTArray<SkString> &stringArray);
SkString list_all(const SkTArray<SkString> &stringArray) {
SkString total;
for (int i = 0; i < stringArray.count(); i++) {
if (i > 0) {
total.append(", ");
}
total.append("\"");
total.append(stringArray[i]);
total.append("\"");
}
return total;
}
/**
* Return a list of configuration names, as a single string of this form:
* "item1", "item2", "item3"
*
* @param configs configurations, as a list of indices into gRec
*/
SkString list_all_config_names(const SkTDArray<size_t> &configs);
SkString list_all_config_names(const SkTDArray<size_t> &configs) {
SkString total;
for (int i = 0; i < configs.count(); i++) {
if (i > 0) {
total.append(", ");
}
total.append("\"");
total.append(gRec[configs[i]].fName);
total.append("\"");
}
return total;
}
static bool prepare_subdirectories(const char *root, bool useFileHierarchy,
const SkTDArray<size_t> &configs,
const SkTDArray<const PDFRasterizerData*>& pdfRasterizers) {
if (!sk_mkdir(root)) {
return false;
}
if (useFileHierarchy) {
for (int i = 0; i < configs.count(); i++) {
ConfigData config = gRec[configs[i]];
SkString subdir;
subdir.appendf("%s%c%s", root, SkPATH_SEPARATOR, config.fName);
if (!sk_mkdir(subdir.c_str())) {
return false;
}
if (config.fBackend == kPDF_Backend) {
for (int j = 0; j < pdfRasterizers.count(); j++) {
SkString pdfSubdir = subdir;
pdfSubdir.appendf("-%s", pdfRasterizers[j]->fName);
if (!sk_mkdir(pdfSubdir.c_str())) {
return false;
}
}
}
}
}
return true;
}
static bool parse_flags_configs(SkTDArray<size_t>* outConfigs,
GrContextFactory* grFactory) {
SkTDArray<size_t> excludeConfigs;
for (int i = 0; i < FLAGS_config.count(); i++) {
const char* config = FLAGS_config[i];
bool exclude = false;
if (*config == kExcludeConfigChar) {
exclude = true;
config += 1;
}
int index = findConfig(config);
if (index >= 0) {
if (exclude) {
*excludeConfigs.append() = index;
} else {
appendUnique<size_t>(outConfigs, index);
}
} else if (0 == strcmp(kDefaultsConfigStr, config)) {
if (exclude) {
SkDebugf("%c%s is not allowed.\n",
kExcludeConfigChar, kDefaultsConfigStr);
return false;
}
for (size_t c = 0; c < SK_ARRAY_COUNT(gRec); ++c) {
if (gRec[c].fRunByDefault) {
appendUnique<size_t>(outConfigs, c);
}
}
} else {
SkDebugf("unrecognized config %s\n", config);
return false;
}
}
for (int i = 0; i < FLAGS_excludeConfig.count(); i++) {
int index = findConfig(FLAGS_excludeConfig[i]);
if (index >= 0) {
*excludeConfigs.append() = index;
} else {
SkDebugf("unrecognized excludeConfig %s\n", FLAGS_excludeConfig[i]);
return false;
}
}
if (outConfigs->count() == 0) {
// if no config is specified by user, add the defaults
for (size_t i = 0; i < SK_ARRAY_COUNT(gRec); ++i) {
if (gRec[i].fRunByDefault) {
*outConfigs->append() = i;
}
}
}
// now remove any explicitly excluded configs
for (int i = 0; i < excludeConfigs.count(); ++i) {
int index = outConfigs->find(excludeConfigs[i]);
if (index >= 0) {
outConfigs->remove(index);
// now assert that there was only one copy in configs[]
SkASSERT(outConfigs->find(excludeConfigs[i]) < 0);
}
}
#if SK_SUPPORT_GPU
SkASSERT(grFactory != NULL);
for (int i = 0; i < outConfigs->count(); ++i) {
size_t index = (*outConfigs)[i];
if (kGPU_Backend == gRec[index].fBackend) {
GrContext* ctx = grFactory->get(gRec[index].fGLContextType);
if (NULL == ctx) {
SkDebugf("GrContext could not be created for config %s. Config will be skipped.\n",
gRec[index].fName);
outConfigs->remove(i);
--i;
continue;
}
if (gRec[index].fSampleCnt > ctx->getMaxSampleCount()) {
SkDebugf("Sample count (%d) of config %s is not supported."
" Config will be skipped.\n",
gRec[index].fSampleCnt, gRec[index].fName);
outConfigs->remove(i);
--i;
}
}
}
#endif
if (outConfigs->isEmpty()) {
SkDebugf("No configs to run.");
return false;
}
// now show the user the set of configs that will be run.
SkString configStr("These configs will be run:");
// show the user the config that will run.
for (int i = 0; i < outConfigs->count(); ++i) {
configStr.appendf(" %s", gRec[(*outConfigs)[i]].fName);
}
SkDebugf("%s\n", configStr.c_str());
return true;
}
static bool parse_flags_pdf_rasterizers(const SkTDArray<size_t>& configs,
SkTDArray<const PDFRasterizerData*>* outRasterizers) {
// No need to run this check (and display the PDF rasterizers message)
// if no PDF backends are in the configs.
bool configHasPDF = false;
for (int i = 0; i < configs.count(); i++) {
if (gRec[configs[i]].fBackend == kPDF_Backend) {
configHasPDF = true;
break;
}
}
if (!configHasPDF) {
return true;
}
if (FLAGS_pdfRasterizers.count() == 1 &&
!strcmp(FLAGS_pdfRasterizers[0], "default")) {
for (int i = 0; i < (int)SK_ARRAY_COUNT(kPDFRasterizers); ++i) {
if (kPDFRasterizers[i].fRunByDefault) {
*outRasterizers->append() = &kPDFRasterizers[i];
}
}
} else {
for (int i = 0; i < FLAGS_pdfRasterizers.count(); i++) {
const char* rasterizer = FLAGS_pdfRasterizers[i];
const PDFRasterizerData* rasterizerPtr =
findPDFRasterizer(rasterizer);
if (rasterizerPtr == NULL) {
SkDebugf("unrecognized rasterizer %s\n", rasterizer);
return false;
}
appendUnique<const PDFRasterizerData*>(outRasterizers,
rasterizerPtr);
}
}
// now show the user the set of configs that will be run.
SkString configStr("These PDF rasterizers will be run:");
// show the user the config that will run.
for (int i = 0; i < outRasterizers->count(); ++i) {
configStr.appendf(" %s", (*outRasterizers)[i]->fName);
}
SkDebugf("%s\n", configStr.c_str());
return true;
}
static bool parse_flags_ignore_error_types(ErrorCombination* outErrorTypes) {
if (FLAGS_ignoreErrorTypes.count() > 0) {
*outErrorTypes = ErrorCombination();
for (int i = 0; i < FLAGS_ignoreErrorTypes.count(); i++) {
ErrorType type;
const char *name = FLAGS_ignoreErrorTypes[i];
if (!getErrorTypeByName(name, &type)) {
SkDebugf("cannot find ErrorType with name '%s'\n", name);
return false;
} else {
outErrorTypes->add(type);
}
}
}
return true;
}
/**
* Replace contents of ignoreTestNames with a list of test names, indicating
* which tests' failures should be ignored.
*/
static bool parse_flags_ignore_tests(SkTArray<SkString> &ignoreTestNames) {
ignoreTestNames.reset();
// Parse --ignoreFailuresFile
for (int i = 0; i < FLAGS_ignoreFailuresFile.count(); i++) {
SkTArray<SkString> linesFromFile;
if (!read_lines_from_file(FLAGS_ignoreFailuresFile[i], linesFromFile)) {
return false;
} else {
for (int j = 0; j < linesFromFile.count(); j++) {
SkString thisLine = linesFromFile[j];
if (thisLine.isEmpty() || thisLine.startsWith('#')) {
// skip this line
} else {
ignoreTestNames.push_back(thisLine);
}
}
}
}
return true;
}
static bool parse_flags_modulo(int* moduloRemainder, int* moduloDivisor) {
if (FLAGS_modulo.count() == 2) {
*moduloRemainder = atoi(FLAGS_modulo[0]);
*moduloDivisor = atoi(FLAGS_modulo[1]);
if (*moduloRemainder < 0 || *moduloDivisor <= 0 ||
*moduloRemainder >= *moduloDivisor) {
SkDebugf("invalid modulo values.");
return false;
}
}
return true;
}
#if SK_SUPPORT_GPU
static bool parse_flags_gpu_cache(int* sizeBytes, int* sizeCount) {
if (FLAGS_gpuCacheSize.count() > 0) {
if (FLAGS_gpuCacheSize.count() != 2) {
SkDebugf("--gpuCacheSize requires two arguments\n");
return false;
}
*sizeBytes = atoi(FLAGS_gpuCacheSize[0]);
*sizeCount = atoi(FLAGS_gpuCacheSize[1]);
} else {
*sizeBytes = DEFAULT_CACHE_VALUE;
*sizeCount = DEFAULT_CACHE_VALUE;
}
return true;
}
#endif
static bool parse_flags_tile_grid_replay_scales(SkTDArray<SkScalar>* outScales) {
*outScales->append() = SK_Scalar1; // By default only test at scale 1.0
if (FLAGS_tileGridReplayScales.count() > 0) {
outScales->reset();
for (int i = 0; i < FLAGS_tileGridReplayScales.count(); i++) {
double val = atof(FLAGS_tileGridReplayScales[i]);
if (0 < val) {
*outScales->append() = SkDoubleToScalar(val);
}
}
if (0 == outScales->count()) {
// Should have at least one scale
SkDebugf("--tileGridReplayScales requires at least one scale.\n");
return false;
}
}
return true;
}
static bool parse_flags_gmmain_paths(GMMain* gmmain) {
gmmain->fUseFileHierarchy = FLAGS_hierarchy;
gmmain->fWriteChecksumBasedFilenames = FLAGS_writeChecksumBasedFilenames;
if (FLAGS_mismatchPath.count() == 1) {
gmmain->fMismatchPath = FLAGS_mismatchPath[0];
}
if (FLAGS_missingExpectationsPath.count() == 1) {
gmmain->fMissingExpectationsPath = FLAGS_missingExpectationsPath[0];
}
if (FLAGS_readPath.count() == 1) {
const char* readPath = FLAGS_readPath[0];
if (!sk_exists(readPath)) {
SkDebugf("readPath %s does not exist!\n", readPath);
return false;
}
if (sk_isdir(readPath)) {
if (FLAGS_verbose) {
SkDebugf("reading from %s\n", readPath);
}
gmmain->fExpectationsSource.reset(SkNEW_ARGS(
IndividualImageExpectationsSource, (readPath)));
} else {
if (FLAGS_verbose) {
SkDebugf("reading expectations from JSON summary file %s\n", readPath);
}
gmmain->fExpectationsSource.reset(SkNEW_ARGS(JsonExpectationsSource, (readPath)));
}
}
return true;
}
static bool parse_flags_jpeg_quality() {
if (FLAGS_pdfJpegQuality < -1 || FLAGS_pdfJpegQuality > 100) {
SkDebugf("%s\n", "pdfJpegQuality must be in [-1 .. 100] range.");
return false;
}
return true;
}
int tool_main(int argc, char** argv);
int tool_main(int argc, char** argv) {
SetupCrashHandler();
SkString usage;
usage.printf("Run the golden master tests.\n");
SkCommandLineFlags::SetUsage(usage.c_str());
SkCommandLineFlags::Parse(argc, argv);
#if SK_ENABLE_INST_COUNT
if (FLAGS_leaks) {
gPrintInstCount = true;
}
#endif
SkGraphics::Init();
setSystemPreferences();
GMMain gmmain;
SkTDArray<size_t> configs;
int moduloRemainder = -1;
int moduloDivisor = -1;
SkTDArray<const PDFRasterizerData*> pdfRasterizers;
SkTDArray<SkScalar> tileGridReplayScales;
#if SK_SUPPORT_GPU
GrContextFactory* grFactory = new GrContextFactory;
#else
GrContextFactory* grFactory = NULL;
#endif
if (FLAGS_dryRun) {
SkDebugf( "Doing a dry run; no tests will actually be executed.\n");
}
if (!parse_flags_modulo(&moduloRemainder, &moduloDivisor) ||
!parse_flags_ignore_error_types(&gmmain.fIgnorableErrorTypes) ||
!parse_flags_ignore_tests(gmmain.fIgnorableTestNames) ||
#if SK_SUPPORT_GPU
!parse_flags_gpu_cache(&gGpuCacheSizeBytes, &gGpuCacheSizeCount) ||
#endif
!parse_flags_tile_grid_replay_scales(&tileGridReplayScales) ||
!parse_flags_jpeg_quality() ||
!parse_flags_configs(&configs, grFactory) ||
!parse_flags_pdf_rasterizers(configs, &pdfRasterizers) ||
!parse_flags_gmmain_paths(&gmmain)) {
return -1;
}
if (FLAGS_verbose) {
if (FLAGS_writePath.count() == 1) {
SkDebugf("writing to %s\n", FLAGS_writePath[0]);
}
if (NULL != gmmain.fMismatchPath) {
SkDebugf("writing mismatches to %s\n", gmmain.fMismatchPath);
}
if (NULL != gmmain.fMissingExpectationsPath) {
SkDebugf("writing images without expectations to %s\n",
gmmain.fMissingExpectationsPath);
}
if (FLAGS_writePicturePath.count() == 1) {
SkDebugf("writing pictures to %s\n", FLAGS_writePicturePath[0]);
}
if (!GetResourcePath().isEmpty()) {
SkDebugf("reading resources from %s\n", GetResourcePath().c_str());
}
}
int gmsRun = 0;
int gmIndex = -1;
SkString moduloStr;
if (!FLAGS_dryRun) {
// If we will be writing out files, prepare subdirectories.
if (FLAGS_writePath.count() == 1) {
if (!prepare_subdirectories(FLAGS_writePath[0], gmmain.fUseFileHierarchy,
configs, pdfRasterizers)) {
return -1;
}
}
if (NULL != gmmain.fMismatchPath) {
if (!prepare_subdirectories(gmmain.fMismatchPath, gmmain.fUseFileHierarchy,
configs, pdfRasterizers)) {
return -1;
}
}
if (NULL != gmmain.fMissingExpectationsPath) {
if (!prepare_subdirectories(gmmain.fMissingExpectationsPath, gmmain.fUseFileHierarchy,
configs, pdfRasterizers)) {
return -1;
}
}
}
Iter iter;
GM* gm;
while ((gm = iter.next()) != NULL) {
if (FLAGS_forcePerspectiveMatrix) {
SkMatrix perspective;
perspective.setIdentity();
perspective.setPerspY(SkScalarDiv(SK_Scalar1, SkIntToScalar(1000)));
perspective.setSkewX(SkScalarDiv(SkIntToScalar(8),
SkIntToScalar(25)));
gm->setStarterMatrix(perspective);
}
SkAutoTDelete<GM> adgm(gm);
++gmIndex;
if (moduloRemainder >= 0) {
if ((gmIndex % moduloDivisor) != moduloRemainder) {
continue;
}
moduloStr.printf("[%d.%d] ", gmIndex, moduloDivisor);
}
const char* shortName = gm->getName();
if (SkCommandLineFlags::ShouldSkip(FLAGS_match, shortName)) {
continue;
}
gmsRun++;
SkISize size = gm->getISize();
SkDebugf("%sdrawing... %s [%d %d]\n", moduloStr.c_str(), shortName,
size.width(), size.height());
if (!FLAGS_dryRun)
run_multiple_configs(gmmain, gm, configs, pdfRasterizers, tileGridReplayScales, grFactory);
}
if (FLAGS_dryRun)
return 0;
SkTArray<SkString> modes;
gmmain.GetRenderModesEncountered(modes);
int modeCount = modes.count();
// Now that we have run all the tests and thus know the full set of renderModes that we
// tried to run, we can call RecordTestResults() to record the cases in which we skipped
// ALL renderModes.
// See http://skbug.com/1994 and https://codereview.chromium.org/129203002/
int testCount = gmmain.fTestsSkippedOnAllRenderModes.count();
for (int testNum = 0; testNum < testCount; ++testNum) {
const SkString &shortNamePlusConfig = gmmain.fTestsSkippedOnAllRenderModes[testNum];
for (int modeNum = 0; modeNum < modeCount; ++modeNum) {
gmmain.RecordTestResults(kIntentionallySkipped_ErrorType, shortNamePlusConfig,
modes[modeNum].c_str());
}
}
bool reportError = false;
if (gmmain.NumSignificantErrors() > 0) {
reportError = true;
}
// We test every GM against every config, and for every raster config also test every mode.
int rasterConfigs = 0;
for (int i = 0; i < configs.count(); i++) {
if (gRec[configs[i]].fBackend == kRaster_Backend) {
rasterConfigs++;
}
}
// For raster configs, we run all renderModes; for non-raster configs, just default renderMode
const int expectedNumberOfTests = rasterConfigs * gmsRun * modeCount
+ (configs.count() - rasterConfigs) * gmsRun;
// Output summary to stdout.
if (FLAGS_verbose) {
SkDebugf("Ran %d GMs\n", gmsRun);
SkDebugf("... over %2d configs [%s]\n", configs.count(),
list_all_config_names(configs).c_str());
SkDebugf("... and %2d modes [%s]\n", modeCount, list_all(modes).c_str());
SkDebugf("... so there should be a total of %d tests.\n", expectedNumberOfTests);
}
gmmain.ListErrors(FLAGS_verbose);
// TODO(epoger): Enable this check for Android, too, once we resolve
// https://code.google.com/p/skia/issues/detail?id=1222
// ('GM is unexpectedly skipping tests on Android')
#ifndef SK_BUILD_FOR_ANDROID
if (expectedNumberOfTests != gmmain.fTestsRun) {
SkDebugf("expected %d tests, but ran or skipped %d tests\n",
expectedNumberOfTests, gmmain.fTestsRun);
reportError = true;
}
#endif
if (FLAGS_writeJsonSummaryPath.count() == 1) {
Json::Value root = CreateJsonTree(
gmmain.fJsonExpectedResults,
gmmain.fJsonActualResults_Failed, gmmain.fJsonActualResults_FailureIgnored,
gmmain.fJsonActualResults_NoComparison, gmmain.fJsonActualResults_Succeeded);
std::string jsonStdString = root.toStyledString();
SkFILEWStream stream(FLAGS_writeJsonSummaryPath[0]);
stream.write(jsonStdString.c_str(), jsonStdString.length());
}
#if SK_SUPPORT_GPU
#if GR_CACHE_STATS
for (int i = 0; i < configs.count(); i++) {
ConfigData config = gRec[configs[i]];
if (FLAGS_verbose && (kGPU_Backend == config.fBackend)) {
GrContext* gr = grFactory->get(config.fGLContextType);
SkDebugf("config: %s %x\n", config.fName, gr);
gr->printCacheStats();
}
}
#endif
#if GR_DUMP_FONT_CACHE
for (int i = 0; i < configs.count(); i++) {
ConfigData config = gRec[configs[i]];
if (kGPU_Backend == config.fBackend) {
GrContext* gr = grFactory->get(config.fGLContextType);
gr->dumpFontCache();
}
}
#endif
delete grFactory;
#endif
SkGraphics::Term();
return (reportError) ? -1 : 0;
}
void GMMain::installFilter(SkCanvas* canvas) {
if (FLAGS_forceBWtext) {
canvas->setDrawFilter(SkNEW(BWTextDrawFilter))->unref();
}
}
#if !defined(SK_BUILD_FOR_IOS) && !defined(SK_BUILD_FOR_NACL)
int main(int argc, char * const argv[]) {
return tool_main(argc, (char**) argv);
}
#endif